The present invention relates to a structure for joining members.
Friction stir welding or joining is a method for interconnecting members to be joined without fusion (see, for example, Patent Literature 1).
In the method, a workpiece comprising stacked members to be joined together is rested on a support tool or backing member. While rotated, a joining tool is pushed on the workpiece to assimilate together the materials softened due to frictional heat and plastic flow through stirring.
Then, the joining tool is released from the workpiece to allow the assimilated materials to solidify, thereby joining the members together.
The joining tool comprises a cylindrical shoulder and a short cylindrical pin coaxially contiguous with the shoulder, protruded as a tip of the tool and smaller in outer diameter than the shoulder.
[Patent Literature 1] JP 2004-136365A
Technical Problems
However, the technique in Patent Literature 1 is not applicable to joining of different members made of materials such as steel on the one hand and aluminum alloy on the other which significantly differ in hardness, softening temperature and other properties.
The invention was made in view of the above and has its object to provide a structure for joining members applicable to even different members.
Solution to Problems
In order to attain the above object, the invention provides first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a fastening member formed with an opening for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, and said auxiliary member inserted into the opening of said fastening member and said holes of the members to be joined, material derived from the auxiliary member being adapted to engage with the fastening member and second member to be joined, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a fastening member formed with an opening for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, and said auxiliary member inserted into the opening of said fastening member and said holes of the members to be joined, an inner surface defining the opening of the fastening member being formed with a peripherally extending groove, material derived from the auxiliary member being adapted to enter into said groove on the inner surface defining the opening of the fastening member and cover a circumference of the hole of the second member to be joined, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a fastening member formed with an opening for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, and said auxiliary member inserted into the opening of said fastening member and said holes of the members to be joined, material derived from the auxiliary member being adapted to engage with the fastening member and be assimilated with the second member to be joined, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a fastening member formed with an opening for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, and said auxiliary member inserted into the opening of said fastening member and said holes of the members to be joined, an inner surface defining the opening of the fastening member being formed with a peripherally extending groove, material derived from the auxiliary member being adapted to enter into said groove on the inner surface defining the opening of the fastening member and be assimilated with the second member to be joined, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a fastening member formed with an opening for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, and said auxiliary member inserted into the opening of said fastening member and said holes of the members to be joined, material derived from the auxiliary member being adapted to be assimilated with the fastening member and engage with the second member to be joined, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a fastening member formed with an opening for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, and said auxiliary member inserted into the opening of said fastening member and said holes of the members to be joined, material derived from the auxiliary member being adapted to be assimilated with the fastening member and cover a circumference of the hole of the second member to be joined, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a fastening member formed with an opening for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, and said auxiliary member inserted into the opening of said fastening member and said holes of the members to be joined, material derived from the auxiliary member being adapted to be assimilated with the fastening member and second member to be joined, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a first fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, a second fastening member formed with a hole for insertion of the auxiliary member and contiguous with the holes of said members to be joined and abutting on the second member to be joined on a side away from said first member to be joined, and said auxiliary member inserted into the hole of the first fastening member, the holes of the first and second members to be joined and the hole of the second fastening member, material derived from the auxiliary member being adapted to engage with the first and second fastening members, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a first fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, a second fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the second member to be joined on a side away from the first member to be joined, and said auxiliary member inserted into the hole of the first fastening member, the holes of the members to be joined and the hole of the second fastening member, material derived from the auxiliary member being adapted to cover circumferences of the holes of the first and second fastening members, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a first fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, a second fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the second member to be joined on a side away from the first member to be joined, and said auxiliary member inserted into the hole of the first fastening member, the holes of the members to be joined and the hole of the second fastening member, material derived from the auxiliary member being adapted to engage with the first fastening member and be assimilated with the second fastening member, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a first fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, a second fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of said members to be joined and abutting on the second member to be joined on a side away from the first member to be joined, and said auxiliary member inserted into the hole of the first fastening member, the holes of the members to be joined and the hole of the second fastening member, material derived from the auxiliary member being adapted to cover a circumference of the hole of the first fastening member and be assimilated with the second fastening member, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a first fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, a second fastening member formed with a hole for insertion of the auxiliary member and contiguous with the holes of said members to be joined and abutting on the second member to be joined on a side away from said first member to be joined, and said auxiliary member inserted into the hole of the first fastening member, the holes of the first and second members to be joined and the hole of the second fastening member, material derived from the auxiliary member being adapted to be assimilated with the first fastening member and engage with the second fastening member, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a first fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, a second fastening member formed with a hole for insertion of the auxiliary member and contiguous with the holes of said members to be joined and abutting on the second member to be joined on a side away from said first member to be joined, and said auxiliary member inserted into the hole of the first fastening member, the holes of the first and second members to be joined and the hole of the second fastening member, material derived from the auxiliary member being adapted to be assimilated with the first fastening member and cover a circumference of the hole of the second fastening member, due to frictional heat and plastic flow.
The invention comprises first and second members to be joined, said members to be joined being stacked one on the other for face-to-face contact and formed with respective, mutually contiguous holes for insertion of an auxiliary member, a first fastening member formed with a hole for insertion of the auxiliary member and contiguous with said holes of the members to be joined and abutting on the first member to be joined on a side away from the second member to be joined, a second fastening member formed with a hole for insertion of the auxiliary member and contiguous with the holes of said members to be joined and abutting on the second member to be joined on a side away from said first member to be joined, and said auxiliary member inserted into the hole of the first fastening member, the holes of the first and second members to be joined and the hole of the second fastening member, material derived from the auxiliary member being adapted to be assimilated with the first and second fastening members due to frictional heat and plastic flow.
Advantageous Effects of Invention
According to a structure for joining members of the invention, excellent effects and advantages will be obtained as follows:
Embodiments of the invention will be described in conjunction with the drawings.
The structure for joining members comprises first and second plate-like members 1 and 2 to be joined which are stacked one on the other for face-to-face contact, a fastening member 5 abutting on the first member 1 to be joined on a side away from the second member 2 to be joined, and an auxiliary member 7.
The auxiliary member 7 is made of aluminum alloy, the second member 2 and the fastening member 5 being made of steel harder and higher in softening temperature than aluminum alloy.
The first and second members 1 and 2 are formed with coaxial holes 3 and 4, respectively, which extend through the respective members in a direction of thickness thereof.
The fastening member 5 is formed with a threaded hole 20 which is coaxial with the holes 3 and 4 of the members 1 and 2 and which extends through the member 5 in a direction of thickness thereof.
Alternatively, the threaded hole 20 may be a blind hole which does not extend through the member. Usable as the fastening member 5 is a nut or a cap nut.
As shown in (a) of
The fastening member 5 may be preliminarily fixed to the first member 1 by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 7 is conducted, using a backing member 6 and a joining tool 10.
The backing member 6 and the joining tool 10 are made of steel harder and higher in softening temperature than aluminum alloy.
The joining tool 10 comprises a short cylindrical pin 8 coaxially contiguous with a tip end surface of a cylindrical shoulder 9. The backing member 6 serves to receive the members 5 and 7.
While rotated, the joining tool 10 is pushed on an end surface, on a side adjacent to the second member 2 to be joined, of the auxiliary member 7 supported by the backing member 6, so that the auxiliary member 7 is softened due to frictional heat and plastic flow as shown in (b) of
Then, as shown in (c) of
Further, as shown in (d) of
Thus, even if the first member 1 to be joined is made of steel just like the second member 2 to be joined or made of material other than steel which is significantly different in hardness, softening temperature and other properties, the members 1 and 2 can be efficiently and reliably joined together.
If the first member 1 to be joined is made of aluminum alloy just like the auxiliary member 7, the material derived from the auxiliary member 7 is assimilated with the first member 1.
If the first member 1 to be joined is relatively thin in comparison with the second member 2 to be joined, advisably the fastening member 5 may be preliminarily fixed to the first member 1 to be joined by welding or other technique. Such preliminary fixing brings about dispersion of shearing force applied by the fastening member 5 to the auxiliary member 7, and prevents rupture of the auxiliary member 7 even if forces are applied to the first and second members 1 and 2 in mutually shifted directions and prevents the first member 1 from being peeled.
The structure for joining members comprises first and second plate-like members 1 and 21 to be joined which are stacked one on the other for face-to-face contact, a fastening member 5 abutting on the first member 1 to be joined on a side away from the second member 21 to be joined, and an auxiliary member 7.
The second member 21 and the auxiliary member 7 are made of aluminum alloy, the fastening member 5 being made of steel harder and higher in softening temperature than aluminum alloy.
The first and second members 1 and 21 are formed with coaxial holes 3 and 22, respectively, which extend through the respective members in a direction of thickness thereof.
The fastening member 5 is formed with a threaded hole 20 which is coaxial with the holes 3 and 22 of the members 1 and 21 and which extends through the member in a direction of thickness thereof.
As shown in (a) of
The fastening member 5 may be preliminarily fixed to the first member 1 to be joined by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 7 is conducted, using a backing member 6 and a joining tool 10.
While rotated, the joining tool 10 is pushed on an end surface, on the side adjacent to the second member 21, of the auxiliary member 7 supported by the backing member 6, so that the auxiliary member 7 is softened due to frictional heat and plastic flow as shown in (b) of
Then, as shown in (c) of
Further, as shown in (d) of
Thus, even if the first member 1 to be joined is made of aluminum alloy just like the second member 21 to be joined or made of material other than aluminum alloy which is significantly different in hardness, softening temperature and other properties, the members 1 and 21 can be efficiently and reliably joined together.
If the first member 1 to be joined is made of aluminum alloy just like the auxiliary member 7, the material derived from the auxiliary member 7 is assimilated with the first member 1 to be joined.
If the first member 1 to be joined is relatively thin in comparison with the second member 21 to be joined, advisably the fastening member 5 may be preliminarily fixed to the first member 1 by welding or other technique; then, such preliminary fixing brings about dispersion of shearing force applied by the fastening member 5 to the auxiliary member 7, and prevents rupture of the auxiliary member 7 even if forces are applied to the first and second members 1 and 21 in mutually shifted directions and prevents the first member 1 from being peeled.
The structure for joining members comprises first and second plate-like members 1 and 2 to be joined which are stacked one on the other for face-to-face contact, a fastening member 23 abutting on the first member 1 on a side away from the second member 2 and an auxiliary member 7.
The fastening member 23 and the auxiliary member 7 are made of aluminum alloy, the second member 2 being made of steel harder and higher in softening temperature than aluminum alloy.
The fastening member 23 is formed with a hole 24 which is coaxial with the holes 3 and 4 of the members 1 and 2 and which extends through the member 23 in a direction of thickness thereof.
Alternatively, the hole 24 may be a blind hole which is opened to the first member 1 to be joined and does not extend through the member 23.
As shown in (a) of
The fastening member 23 may be preliminarily fixed to the first member 1 to be joined by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 7 is conducted, using a backing member 6 and a joining tool 10.
The backing member 6 serves to receive the members 23 and 7.
While rotated, the joining tool 10 is pushed on an end surface, on a side adjacent to the second member 2, of the auxiliary member 7 supported by the backing member 6, so that the auxiliary member 7 is softened due to frictional heat and plastic flow as shown in (b) of
Then, as shown in (c) of
Further, as shown in (d) of
Thus, even if the first member 1 to be joined is made of steel just like the second member 2 to be joined or made of material other than steel which is significantly different in hardness, softening temperature and other properties, the members 1 and 2 can be efficiently and reliably joined together.
If the first member 1 to be joined is made of aluminum alloy just like the auxiliary member 7, the material derived from the auxiliary member 7 is assimilated with the first member 1 to be joined.
If the first member 1 to be joined is relatively thin in comparison with the second member 2 to be joined, advisably the fastening member 23 may be preliminarily fixed to the first member 1 to be joined by welding or other technique. Such preliminary fixing brings about dispersion of shearing force applied by the fastening member 23 to the auxiliary member 7, and prevents rupture of the auxiliary member 7 even if forces are applied to the first and second members 1 and 2 in mutually shifted directions and prevents the first member 1 from being peeled.
The structure for joining members comprises first and second plate-like members 1 and 21 to be joined which are stacked one on the other for face-to-face contact, a fastening member 23 abutting on the first member 1 to be joined on a side away from the second member 21, and an auxiliary member 7.
The second member 21, the fastening member 23 and the auxiliary member 7 are made of aluminum alloy.
The fastening member 23 is formed with a hole 24 which is coaxial with the holes 3 and 22 of the first and second members 1 and 21 to be joined and which extends through the member 23 in a direction of thickness thereof.
Alternatively, the hole 24 may be a blind hole which is opened to the first member 1 to be joined and does not extend through the member 23 in the direction of thickness thereof.
As shown in (a) of
The fastening member 23 may be preliminarily fixed to the first member 1 to be joined by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 7 is conducted, using a backing member 6 and a joining tool 10.
While rotated, the joining tool 10 is pushed on an end surface, on the side adjacent to the second member 21, of the auxiliary member 7 supported by the backing member 6, so that the auxiliary member 7 is softened due to frictional heat and plastic flow by shown in (b) of
Then, as shown in (c) of
Further, as shown in (d) of
Thus, even if the first member 1 to be joined is made of aluminum alloy just like the second member 21 to be joined or made of material other than aluminum alloy which is significantly different in hardness, softening temperature and other properties, thus the members 1 and 21 to be joined can be efficiently and reliably joined together.
If the first member 1 to be joined is made of aluminum alloy just like the auxiliary member 7, the material derived from the auxiliary member 7 is assimilated with the first member 1 to be joined.
If the first member 1 to be joined is relatively thin in comparison with the second member 21 to be joined 21, advisably the fastening member 23 may be preliminarily fixed to the first member 1 to be joined by welding or other technique. Such preliminary fixing brings about dispersion of shearing force applied by the fastening member 23 to the auxiliary member 7, and prevents rupture of the auxiliary member 7 even if forces are applied to the first and second members 1 and 21 to be joined in mutually shifted directions and prevents the first member 1 to be joined from being peeled.
The structure for joining members comprises first and second plate-like members 11 and 12 to be joined which are stacked one on the other for face-to-face contact, a first fastening member 15 abutting on the first member 11 to be joined on a side way from the second member 12 to be joined, a second fastening member 16 abutting on the second member 12 on a side away from the first member 11 to be joined, and an auxiliary member 19.
The auxiliary member 19 is made of aluminum alloy, the first and second fastening members 15 and 16 being made of steel harder and higher in softening temperature than aluminum alloy.
The first and second members 11 and 12 to be joined are formed with holes 13 and 14, respectively, which are coaxial and extend through the respective members in a direction of thickness thereof.
The first and second fastening members 15 and 16 are formed with threaded holes 25 and 26, respectively, which are coaxial with the holes 13 and 14 of the first and second members 11 and 12 to be joined and which extend through the respective members in the direction of thickness thereof.
Alternatively, the holes 25 and 26 may be not threaded holes but mere holes extending through the direction of thickness thereof.
As shown in (a) of
The first and second fastening members 15 and 16 may be preliminarily fixed to the first and second members 11 and 12 to be joined, respectively, by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 19 is conducted, using a backing member 18 and a joining tool 10.
The backing member 18 and the joining tool 10 is made of steel harder and higher in softening temperature than aluminum alloy.
The joining tool 10 comprises a short cylindrical pin 8 coaxially contiguous with a tip end of a cylindrical shoulder 9. The backing member 18 serves to receive the members 15 and 19.
The backing member 18 is formed with, at a center of its portion receiving the fastening members 15 and 16, a recess 17 adapted to support the end surface of the auxiliary member 19.
While rotated, the joining tool 10 is pushed on an end surface, on a side adjacent to the second member 12, of the auxiliary member 19 supported by the backing member 18, so that the auxiliary member 19 is softened due to frictional heat and plastic flow as shown in (b) of
Then, the joining tool 10 is released from the auxiliary member 19 to allow the material derived from the auxiliary member 19 and covering the circumference of the threaded hole 26.
Then, as shown in 5(c) of
Then, as shown in (d) of
Thus, even if the first and second members 11 and 12 to be joined are made of materials such as steel on the one hand and aluminum alloy on the other hand which are significantly different in hardness, softening temperature and other properties, thus the members 11 and 12 to be joined can be efficiently and reliably joined together.
If the first and second members 11 and 12 to be joined are made of aluminum alloy just like the auxiliary member 19, the material derived from the auxiliary member 19 is assimilated with the first and second members 11 and 12 to be joined.
The structure for joining members comprises first and second members 11 and 12 to be joined, a first fastening member 15 abutting on the first member 11 on a side away from the second member 12 to be joined, a second fastening member 27 abutting on the second member 12 on a side away from the first member 11 to be joined, and an auxiliary member 19.
The second fastening member 27 is made of aluminum alloy just like the auxiliary member 19.
The second fastening member 27 is formed with a hole 28 which is coaxial with the holes 13 and 14 of the first and second members 11 and 12 to be joined and extends through the member 27 in a direction of thickness thereof.
As shown in (a) of
The first and second fastening members 15 and 27 may be preliminarily fixed to the first and second members 11 and 12 to be joined, respectively, by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 19 is conducted, using a backing member 18 and a joining tool 10.
The backing member 18 serves to receive the first fastening member 15 and the auxiliary member 19.
While rotated, the joining tool 10 is pushed on an end surface, on a side adjacent to the second member 12 to be joined, of the auxiliary member 19 supported by the backing member 18, so that the auxiliary member 19 is softened due to frictional heat and plastic flow and the material derived from the auxiliary member 19 is assimilated with the second fastening member 27 as shown (b) of
Then, the joining tool 10 is released from the auxiliary member 19 to allow the material derived from the auxiliary member 19 and assimilated with the second fastening member 27 to solidify.
Then, as shown in (c) of
Then, as shown in (d) of
Thus, even if the first and second members 11 and 12 to be joined are made of materials such as steel on the one hand and aluminum alloy on the other hand which are significantly different in hardness, softening temperature and other properties, thus the members 11 and 12 to be joined can be efficiently and reliably joined together.
If the first and second members 11 and 12 to be joined are made of aluminum alloy just like the auxiliary member 19, the material derived from the auxiliary member 19 is assimilated with the first and second members 11 and 12 to be joined.
The structure for joining members comprises first and second members 11 and 12 to be joined, a first fastening member 29 abutting on the first member 11 on a side away from the second member 12 to be joined, a second fastening member 16 abutting on the second member 23 on a side away from the first member 11 to be joined, and an auxiliary member 19.
The first fastening member 29 is made of aluminum alloy just like the auxiliary member 19.
The first fastening member 29 is formed with a hole 30 which is coaxial with the holes 13 and 14 of the first and second members 11 and 12 to be joined and which extend through the member 29 in a direction of thickness thereof.
As shown in (a) of
The first and second fastening members 29 and 16 may be preliminarily fixed to the first and second members 11 and 12 to be joined, respectively, by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 19 is conduced, using a backing member 18 and a joining tool 10.
The backing member 18 serves to receive the members 29 and 19.
While rotated, the joining tool 10 is pushed on an end surface, on a side adjacent to the second member 12 to be joined, of the auxiliary member 19 supported by the backing member 18, so that as shown in (b) of
Then, the joining tool 10 is released from the auxiliary member 19 to allow the material derived from the auxiliary member 19 covering the circumference of the threaded hole 26 to solidify.
Then, as shown in (c) of
Then, the joining tool 10 is released from the auxiliary member 19 to allow the material derived from the auxiliary member 19 and assimilated with the first fastening member 29 to solidify, thus completing the joining of the first and second members 11 and 12 to be joined.
Thus, even if the first and second members 11 and 12 to be joined are made of materials such as steel on the one hand and aluminum alloy on the other hand which are significantly different in hardness, softening temperature and other properties, thus the members 11 and 12 can be efficiently and reliably joined together.
If the first and second members 11 and 12 to be joined are made of aluminum alloy just like the auxiliary member 19, the material derived from the auxiliary member 19 is assimilated with the first and second members 11 and 12 to be joined.
The structure for joining members comprises first and second members 11 and 12 to be joined, a first fastening member 29 abutting on the first member 11 on a side away from the second member 12 to be joined, a second fastening member 27 abutting on the second member 12 on a side away from the first member 11 to be joined, and an auxiliary member 19.
The first and second fastening members 29 and 27 are made of aluminum alloy just like the auxiliary member 19.
The first and second fastening members 29 and 27 are formed with holes 30 and 28, respectively, which are coaxial with the holes 13 and 14 of the first and second members 11 and 12 to be joined and which extend through the respective members 29 and 27 in a direction of thickness thereof.
As shown in (a) of
The first and second fastening members 29 and 27 may be preliminarily fixed to the first and second members 11 and 12 to be joined, respectively, by welding or other technique.
As shown in (d) of
The above-mentioned shaping of the auxiliary member 19 is conducted, using a backing member 18 and a joining tool 10.
The backing member 18 serves to receive the members 29 and 19.
While rotated, the joining tool 10 is pushed on an end surface, on a side adjacent to the second member 12 to be joined, of the auxiliary member 19 supported by the backing member 18, so that as shown in (b) of
Then, the joining tool 10 is released from the auxiliary member 19 to allow the material derived from the auxiliary member 19 and assimilated with the second fastening member 27 to solidify.
Then, as shown in (c) of
Then, the joining tool 10 is released from the auxiliary member 19 to allow the material derived from the auxiliary member 19 and assimilated with the first fastening member 29 to solidify, thus completing the joining of the first and second members 11 and 12 to be joined.
Thus, even if the first and second members 11 and 12 to be joined are made of materials such as steel on the one hand and aluminum alloy on the other hand which are significantly different in hardness, softening temperature and other properties, thus the members 11 and 12 can be efficiently and reliably joined together.
If the first and second members 11 and 12 to be joined are made of aluminum alloy just like the auxiliary member 19, the material derived from the auxiliary member 19 is assimilated with the first and second members 11 and 12 to be joined.
It is to be understood that a structure for joining members according to the invention is not limited to the above embodiments and that various changes and modifications may be made without departing from the scope of the invention.
Industrial Applicability
A structure for joining members according to the invention is applicable to joining and assembling of various parts and components.
Number | Date | Country | Kind |
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2006-304960 | Nov 2006 | JP | national |
2007-015557 | Jan 2007 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/001227 | 11/9/2007 | WO | 00 | 4/28/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/056448 | 5/15/2008 | WO | A |
Number | Date | Country |
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2000 141066 | May 2000 | JP |
2003 266183 | Sep 2003 | JP |
2004 136365 | May 2004 | JP |
2005 288525 | Oct 2005 | JP |
2006 136906 | Jun 2006 | JP |
2006 289409 | Oct 2006 | JP |
Number | Date | Country | |
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20100064494 A1 | Mar 2010 | US |